Telegraph way station system



May 2, 1961 G. G. LIGHT ErAL TELEGRAPH WAY STATION SYSTEM Filed sept. 12. 1957.

16 Sheets-Sheet 1 .L M M o Y 0 N E T E N N T T R E H H V m m m m L W T l CU. .Im A h. G w. Y Du zoCw .22.25F ||^T| wm ...m5 9.x

5.x ma.; IIAI mmm o m lvl mw GNN N En. .UWE IIVII .550mm v AN 55u28 May 2, 1961 G. G. LIGHT E'rAL 2,982,809

TELEGRAPH WAY STATION SYSTEM Filed Sept. 12, 1957 16 Sheets-Sheet 2 ODD KEYSET OUTPUT 7e 9o To FIG. 3

JNVENTORS o, GG G. LIGHT By w. J. wlcHTENDAHL WIM/Mv ATTORNEY F'IG.2

May 2, 1961 G. G. LIGHT ErAL TELEGRAPH WAY STATION SYSTEM 16 Sheets-Sheet 3 Filed Sept. 12, 1957 .lm .0E 91.4

GSTM

INVENTORS G. G. LIGHT W. J. WICHTENDAHL PA m mm vm mm Nm WOT- mm mm NE OPI AT TORNE Y May 2, 1961 G. G. LIGHT ETAL 2,982,809

TELEGRAPH WAY STATION SYSTEM Filed Sept. 12, 1957 16 Sheets-Sheet 4 ATTORNEY 16 Sheets-Sheet 5 fm f INVENT'oRs May 2,l 1961 G. G. LIGHT ErAL TELEGRAPH wAY STATION SYSTEM Filed Sept. 12, 1957 G. G. LIGHT W. J. WICHTENDAHL AT TORNE Y May 2, 1961 G. G. LIGHT ETAL 2,982,809

TELEGRAPH WAY STATION SYSTEM Filed Sept. l2, 1957 16 Sheets-Shea?l 6 xTR REQUEST TO FIG. 7

m 9' Lx.

i N n r In lo g E o l j j J j j J j j j j INVENTORS l to G. G LIGHT 0 By w. J. WICHTENDAHL E mm ATTORNEY May 2, 1961 G. G. LIGHT ETAL 2,982,809

TELEGRAPH WAY STATION SYSTEM Filed sept. 12, 1957 16 sheets-sheet 7 TAPE ARM (D Q Lx..

INVENTORS G. G. LIGHT By w. J. WICHTENDAHL www ATTORNEY FIG.7

May 2, 1961 G. G. LIGHT Er-AL 2,982,809

TELEGRAPH WAY STATION SYSTEM W. WICHTENDAHL )www ATTORNEY OUTPUT May 2, 1961 G. G. LIGHT ETAL 2,982,809

TELEGRAPH WAY STATION SYSTEM Filed sept. 12, 1957 1e sheets-sheet 9 TO FIG. 8

IN VEN TORS G. G. LIGHT By w. J. WICHTENDAHL ATTORNEY May 2, 1961 G. G. LIGHT ETAL TELEGRAPH WAY STATION SYSTEM 16 Sheets-Sheet 10 Filed Sept. 12, 1957 INVENTORS G. G. LIGHT By w. J. WICHTENDAHL ATTORNEY ozGnEm m May 2, 1961 G. G. LIGHT ETAL TELEGRAPH WAY STATION SYSTEM 16 Sheets-Sheet 1-1 Filed Sept. l2, 1957 May 2, 1961 G. G. LIGHT ETAL TELEGRAPH WAY sTATloN SYSTEM L Q .ol oF M 2 S D 1 M N .t T .CIL e NT. e E HH m Vmm .r WLM .MM GJ. Qh- G.W 1 7 1. flu Y F B m J, 9 m. F o T 7. 5 9 1 om. l mi t w o s N- m m l wm- .l F

ATTORNEY May 2, 1961 G. G. UGH-r AErm 2,982,809

TELEGRAPH WAY STATION SYSTEM L9 By w. J. WICHTENDAHI.

AT TORNEY May 2, 1951 G. G. LIGHT ETAL 2,982,809

TELEGRAPH WAY STATION SYSTEM med sept. 12, 1957 1e sheets-sheet 14 INVENTORS G. G. LIGHT ATTORNEY NBN W. J. WICHTENDAI-IL mmm QON

COMPUTER INPUT *WIJ May 2, 1961 G. G. LIGHT ETAL TELEGRAPH WAY STATION SYSTEM 16 Sheets-Sheet 15 Filed Sept. 12, 1957 ATTORNEY May 2, 1961 G. G. LIGHT ErAL 2,982,809

TELEGRAPH WAY STATION SYSTEM Filed Sept. 12, 1957 16 Sheets-Sheet 16 v I INVENTORS N l G. G. LIGHT la BY w. J. WIGHTENDAHL WMM ATTORNEY United States Patent TELEGRAPH WAY STATION SYSTEM George G. Light, Scarsdale, and William J. Wichtendahl, New York, N.Y., assignors to The Western Union Telegraph Company, New York, NX., a corporation of New York Fired sept. 12, 1957, ser. No. 683,624

16 claims. (ci. 11s-2) This invention relates to a telegraph way station system, and more particularly to a system for etiecting Way station selection and selective communication between a main station, such as a central or terminal station, and the various way stations in a more expeditious manner.

In any Way circuit arrangement that provides for individual station selection, some system of controls is necessary and some means must be provided for operatively connecting the controls in the circuit when control functions are to be performed and for disconnecting them when the control functions have been completed. Long open intervals and gating arrangements based on precise timed intervals are sometimes used, and additional safeguards must also be provided to assure that the control signals are not construed as message characters and that message characters do not function as control signals.

In a way circuit system in accordance with the instant invention, each way station has one or more keysets for transmitting keyset signals and also a printer for receiving teleprinter traflic. A transmitting distributor and a receiving distributor are provided at the central station and at each of the way stations, for transmitting and receiving keyset and teleprinter traffic, and these same distributors are also used for generating and reading control signals. When the line is idle all control circuits are activated and are responsive to particular teleprinter characters that are transmitted for control purposes. The cutting in and cutting out of the control circuits are based on the principle that either keyset or teleprinter trac will always begin with a particular significant start character not otherwise used for other control .functions and that transmission of a message ordinarily will be continuous.

Any time that transmission is stopped, the control circuits are automatically cut in. Therefore, should normal transmission be interrupted for any reason, guard circuits function to assure that the significant start control character is again transmitted just ahead of the resumed message transmission. Thisis of particular importance since the way stations, in addition to a keyset and a receiving printer, may have a tape transmitter for sending teleprinter traic, and if transmission is interrupted, as by a tight tape condition, the start control character will automatically be transmitted before resumption of signds from the tape.

The Way stations are invited on a sequential basis, and in order to conserve circuit time each station upon being invited has means operative in the event that it has no trailic to send for automatically transmitting the invitation character for the next station in the sequence.

One of the objects ofthe instant invention is to provide a way station system in which a plurality of stations in a Way circuit are invited in rotation for the purpose of sending messages to the main station, and in which the time required for the invitation cycle is greatly reduced by means at the way stations operative in the event that an invited station has no message to transmit or does' not have an allotted number of messages to'transmit, for

Frlce automatically sending an invitation signal to the succeeding station in the circuit.

Another object is the provision of a` way station system, of the character described, in which when a way station having message material to transmit is invited, the succeeding way station is invited automatically at the end of the transmission from the invited Way station.

A further object is to provide, in a way station system, means for programming the invitation cycle to invite a selected way station a predetermined number of times during each invitation cycle, and' in which when the selected station does not have the allotted number of messages to transmit it automatically signals that it has no further messages by inviting the succeeding station.

Still another object is a provision for skipping closedf out way stations wherein the next succeeding way station is invited to send when the way station prior to a closedout station completes its message transmission or attempts to invite the closed-out station.

An additional object is to provide a way station system in which the way stations may send and receive both keyset and teleprinter messages to and from the main station, with means for differentiating between keyset traic and teleprinter tra'ic.

Other objects and advantages will be apparent from the following detailed description of a system embodying the principles of the instant invention, taken inconnection with the accompanying drawings in which:

Fig. 1 diagrammatically indicates the basic components of the way Wire system;

Figs. 2, 3, 4 and 5.v collectively comprise aschematic circuit diagram of the equipment and connections at one of the way stations;

`Figs. 6 and 7 together show additional circuitry required in the event that a tape transmitter for sending teleprinter traic is utilized with the way station of Figs. 2 to 5;

Figs. 8, 9, 10, l1, l2, 13, 14, 15 and 16 collectively comprise a schematic circuit diagram of the equipment and connections at the central, or terminal, station;

Fig. 17 shows the manner in which Figs. 2 to 7 should. be arranged with respect to one another; and

Fig. 18 similarly shows how Figs. 8 to 16 should be arranged.

Referring to Fig. 1, there is shown a way wire system in diagrammatic form, in which a way wire circuit L extends from a central or terminal station to a plurality of way stations, of which the rst and last stations are depicted. The terminal station includes a receiving distributor 20 for receiving keyset messages andY also teleprinter messages incoming frorn the way stations, and a transmitting distributor 22 for transmitting control signals and messages to the way stations. Control apparatus 23 is responsive to incoming signals over line L and includes means for distinguishing between keyset tratlic and teleprinter trathc and for applying the keyset signals to receiving apparatus such as data processing equipment, for example, a computer 25, and receiving answer-back signals therefrom for retransmission to a calling keyset, and for applying incoming teleprinter message lsignals to a re'- ceiving teleprinter 25. The particular nature or kind of the data processing equipment at the central station responsive to'the keyset signals, or the purpose for which it is employed does not per se form a part of the instant invention; such" apparatus may, for example, comprise apparatus for magnetically or otherwise storing signals representing a running inventory in regard to merchandise stocks, supplies or other items, card punching and accounting machines, reservation systems for airlines and railroads, and other known equipment.

Each` way station includes receiving and transmitting distributorsl 2u and' 22.', control equipment 253, and a mitter 26' also is provided for transmitting teleprinter Y traic tothe central station, in which case the printer 2-5' willalso print the outgoing messages.

General descrip-tion of operation By .pushing a request buttonv at any of the way stations, theV operator at that station stores the fact that there is traiiicy (either keyset or teleprinter) at that station tobe transmitted to the main station. v If the line circuit L is idle, .pushing the button also sends a 25 millisecond open tothe line, and Ythis open informs the central station that some waystation'has traic'to be picked'up. Due to the fact thatftheA generation of several opens almost simultaneously may be cause a teleprinter character to Vappear on the line, 4the stations are prevented from reading any characters until approximately 0.5 second after the recognition ofthe open. The open also puts on a lockout at all stations and this lockout prevents an open fromrgoing to the line when anyfmore request buttons are pushed. After allowing 'approximately one second for the reading circuitsra't the stations to becomeactive, one of the stations, preferably the main station as illustrated herein, automatically ,sends a particular selecf tion character to invite the first Waystat'io'n in the invitation sequence (assume this characteris Ythe'letter B). The character reading circuits, such as groups of relays, at the stations insure that the rststation is the only one that can respond to the character B when used as a station selection character. l -If the first station has tomatically sends a particular selection character to. invite the second station in the invitation sequence (assume this character isthe letter C) in response to the `B. On the other hand, if the first lstation has keyset trailic to transmit, it sends a particular functional character, Vsuch as the letter S, followed by the keyset data. The S informs the central oice that the information followingit is key- Y set data forthe data processing equipment, fore'xample,

reply only after a keyset message has been sent therefrom. Y i

If the first way station has teleprinter traffic to transmit,

the characterY Space is transmitted followed by the teleprinter trac, thistrac being sent by means of a tape transmitter at the station.` The Space character cuts out all readers and informsy the central station that the information following is to be sent to the receiving printer there.Y The fact that the calling station is transmitting allows the Space to cut in the printer at that station. If transmission is interrupted, as by a tight tape condition or other reason, it must Vbe stopped long enough to allow the readers to cut in. VWhen transmission is to be resumed, it is automatically preceded by a Space to cut outV all readers. At the end ofthe message the printer reads an end-of-message signal comprising FigureShift, H, Le., upper case H, and closes a contact which cuts out the printer and transmitter. If the transmitter is stopped for a predetermined period, for example, 20 seconds, theV to the keyset, the main station automatically Vsends the tive'system disclosed, comprises a succession vof characters Y i stored on contacts of the keyset, which provide buffer storage, each ofwhich vcharacters contains four intelligence code pulses in binary. form, commonly referred Ato 'as' fbits which is an abbreviation for binary digits.V Preferably, a fifth bit is added to each character to provide an odd parity check. The live bits Yof eachV character Waiting traic, the main station sendsrB, the iirst station a're set serially to the line, combined with start and stop pulses to form start-stop permutation code telegraph characters. At the control center, or main station, the received characters are checked for odd parity,rand the fourV intelligence bits of each character are sent to the computer or other data processing equipment in parallelform. At the endof an incoming keyset message, they data Y processing equipment instantly prepares a reply to be are converted intoY start-stop permutation'code telegraph characters as described above. The characterfS cuts out all readers (which in the meantime have been cutv in) V and allows the answerback information to be 'sent to theY calling keyset. 'Ihe characters are checked for parity and the four kintelligence bitsiof each character Y,are applied to the input of the calling keyset: and energize lamps or` ,other signal devices. VThere is no need to .select the proper keyset`stationv in orderto Ysend the replybecause Y by their nature the'keyset of a kcalling station acceptsja selection Vcharacter C to invite the second station in the invitationrcycle.V The second station reacts tofthe C character in the same manner as the first station reacted to the B character except that if therefis no traic'it automatically sends another particular selection character to invite the third station'. This continues with each station inviting the next, Vif it has no' trati'ic, until the last station is invited, and if the last station has no traic it automatically sends a Line Feed character.

If any traffic had been received during an invitation cycle (inviting the first through the'last stations), the cycle is repeated. If no traic had been received, a character (assume this character is the letter A) is sent to l remove the lockout, and removing the lockout permits an open to go to the line if a request button is pushed.'

. The invitation cycle can be programmed to invite busy 'Y stations more frequently, since there is a switch for each station which permits it to be invited 0, l, 2, 3,-'4 or 5 times. If a station is closed out (invitedV 0 times) theV main station` automatically sends the invitation character to the next station in the sequence when it receives the character for the closed-out station. For example, if the second station was closed out, and the first station had no B sends C, andthe main station receives CV and sends theV invitation character for the third station. If astation is closed out and the station before it has traflc, the Yrnain station will invite the station beyond the closed-out station at the endof the message. If a station is allotted two or more successive messages and hence is to be inV vited more than once, it is invited 2, 3, 4 or 5 times(deV pending upon the switch setting) in Ysuccession until av No answer isV received. The No answer in such case is when the station does not have its allotted number of messages to transmit, and upon termination of its/trahie sends thev invitation character of the next station.

Since power is not turned on at all wayfstations at.

the same time, it is possible for a station'to come on during the transmission of a message. To prevent the messa'ge traffic 'from acting like signal characters, the Vstation' can not respond to signals until Vthe line is'idle forV one second. To prevent the request signal from interfering with trailic, the lockout is on when the power is turned on. No station can send' a request signal at Vthe time the circuit is turned-on, but the main station initiates an invitation cycle at definite periods of time, for example,

every ten minutes, if no requests are received. 'Thus the trah'c from the first station will be picked up ten minutes after the circuit is turned on.

The main station can only send telepriuter trac when the line is idle or at the end of an invitation cycle. If the circuit is idle, a short open is sent to busy all stations and then there is a wait for the readers to cut in before the transmitter is started. lf the circuit is busy the transmitter is started upon receipt of a No answer from the last station, which in this case is a Line Feed character if the station had no message to transmit, or at the end of the answerback to the last station in the event that it had keyset trac, or upon receipt of lau end-of-message signal in the case of teleprinter traffic from the station.

The character required to select the desired station must be in the tape followed 'by a Space character; the

character selects the way station printer and the Space cuts in the printer and cuts out the readers. If transmission is stopped, it must be stopped long enough to allow the readers to cut in and transmission must be preceded by Space if it is restarted. If transmission is restarted without sending Space, .the printer is cut out, and also if the transmitter does not start for twenty seconds, the printer is cut out. When the printer receives Figure Shift, H, Letter Shift, it is cut out.

Detailed description of way station circuits Figs. 2 to 5 inclusive show the circuitry of a Way station essentially comprising the output portion 27a of a keyset, Fig. 2, a transmitting distributor 22', Fig. 3, a receiving printer 25, Fig. 4, and a receiving distributor and the input portion 27b of the keyset, Fig. 5. The brush arm 62 of the transmitting distributor 22 is continuously rotated at constant speed by a motor so long as the station is open lfor the transmission andreception of trafc. Normally the distributor is shorted out, with respect to the line L, by a circuit comprising a conductor 7S, switch arm and contacts of bank B of a rotary switch RS-l, Fig. 2, conductors 79 and 86, Fig. 3, and closed contacts 3 of a relay K18, and conductor 77, so that the distributor will not be in the line circuit until the keyset is ready to send to the line L. The start-stop receiving distributor 2G of Fig. 5, however, is normally in circuit with the tongue of a line receiving relay LR1.

Figs. 6 and 7 show additional circuits which are required when a tape transmitter 26' is employed for transmitting teleprinter trafc from the way station. Links y1, y2 and y3, respectively are inserted between pairs of terminals 2 and 3, 4 and 5, and 6 and 7, when the tape transmitter is not employed; the removal of these links and the connection of the row of terminals 1 to 1S of a cable seen at the bottom of Fig. 3 to a corresponding row of terminals from conductors, Figs. 6 and 7, causes the tape transmitter to be included in the Way station circuit.

In the drawings the various control, reading and coding relays are designated Eby the reference character K followed by a number, and are so referred to in the following description.

Functions of K12 (Fig. 4).-Due to the fact that a station may be turned on during a control sequence, it must be prevented from responding to any signals until it is certain that the line L is idle. The start magnet 46, Fig. 5, of the receiving distributor 20 can not be operated by a spacing pulse from the line until K12 is operated by a grid-controlled gas tube V7, Fig. 4, which tube preferably is a thyratron. If the line L stays marking, the grid of V7 is above ground and it conducts after the cathode warm-up time (approximately ten seconds). If the line goes spacing, the grid of V7 is driven negative over a circuit from the tongue of the line relay LRl, solid ring 46 of the distributor 20', conductor 47, armature 5 and contact 4 of K12, and rectiier 49. When the line goes marking, the grid of V7 tends to charge to a positive voltage. If the warm-up time is completed, V7 conducts when its grid reaches ground potential; if the warm-up time is not completed the grid potential cori@4 tinues to rise and V7 conducts when the warm-up time is completed, where upon K12 is operated through V7. When K12 operates it locks up to ground through its contacts 3 thereby shorting out V7, and K12 remains locked up so long as the power is turned on at the station. The operation of K12 closes a path between the tongue of the receiving line relay LR21, solid ring 46 of receiving distributor 20', conductor 47, armature 5 and contact 6 of the relay, conductor 48, segments 42 of the distributor and brush arm 41 to the operate winding of the start magnet 49 to energize the latter and release the distributor brushes for rotation by a constant speed motor through -a slip clutch in known manner.

Character reading circuit-The start (spacing) pulse of a received character operates the start magnet 40 of the receiving distributor 20 causing the brushes to make one revolution. The brushes pass over segment 1 during the lirst pulse of the received character, segment 2 during the second pulse, etc. The segments 1 to 5 are each positioned with respect to the solid ring 46 so that the middle of a signal pulse is received by the segment. The segments 1 to 5 are respectively connected to vacuum tubes V1 to V5 which control characterreading relays KZt to K24. If the first pulse of the receivedv character is marking, V1 conducts,'and if'it is spacing V1 is cut o, and tubes V2 to V5 operate in a corresponding manner. It V1 conducts, K2() operates. During the second pulse if marking in character K21 is operated; if the third pulse is marking K22 is operated; during the fourth pulse if marking K23 is operated; and during the Eth pulse if marking K24 operates. For example, if the character Y is received, K20, K22 and K24 are operated,

When the brushes pass over segment 6 of the distributor, K11 of Fig. 3 operates through a grid-controlled gas tube V6, such as a thyratron, the operating circuit comprising the Winding of K11, conductor 54 segments 52 and 6 of the distributor, conductor 56, energized tube V6, and the grounded armature 2 and contact 1 of K10. Kil has slow release characteristics due to a resistance R5 connected across its winding. The operation of K11 applies ground potential from its armature 2 and contact 3 over conductor 55, armature 4 and contact 3 of K13, Fig. 4, and conductor 58 to probe through the series of contacts of K214i, K23, K22, K21 and K20.

if, for example, the character E (first pulse marking) is received, the ground pulse from K11 (probe pulse) iinds a path from conductor 5S through armatures and contacts of kdeenergized K24 to K21 and appears at contact T9 of energized KM): If the character Blank (all pulses spacing) is received, the probe pulse appears at contact T7 of KM. lf the control character S (first and third pulses marking) is received, the probe pulse appears at contact B6 of K20. The invitation and selection characters provide outputs on terminals t2 and t4 of the groups of terminals t1 to t4 in circuit with the armatures and contacts of KZti to K24, depending upon the connections of links selectively inserted between these terminals. In the present case, links yS, y6, y7 and yS are connected to cause the station to respond to its invitation character which is assumed to be the letter B.

Request and lockout circuits- As hereinbefore stated, if no traffic had been received by the central station during an invitation cycle, the control character A subsequently is transmitted by the central station to remove the lockout at the various Way stations thereby to permit an open to go to the line if a request button is pushed at one of the stations. Upon receipt of the Qharacter A (irst and second pulses marking) a lockout relay K10, Fig. 3, is operated over a circuit comprising its righthand winding, conductor 57, contacts B8 of energized Kif-3 of Fig. 5, contacts it of K16, contact T6 and armature 5 of energized K21, and the back contacts T4, T1 and 4 of deenergized KZZ, K23 and K24, conductor 58, contact 3 and armature 4 of K13, conductor 55, and

V contact?, and armature 2 of koperated K11 to ground. The operation of K10 Vat its armature 2 removes ground from thercathode of V6, causing the tube to extinguish since its cathode is then connected to positive battery through a `resistance R7 which Yhas substantially the same value as resistance R6 in the plate circuit of the tube.

` When it is desired to send from the keyset, a request .button V31, Fig. 3, is-depressed and applies ground to a circuit including contacts 1 of K6 and the Winding of K9, causing K9 to operate. The latter relay locks up over a Y circuit including itsY contacts and conductor 74 to level resistance R9 connected across its winding. After apapproximately `25 milliseconds K19 releases and at its contacts 1 itVrecloses/the line L. The spacing signal on the line causes a cold cathode tube V10 to conduct, and this causeszrelease'of` relay K10 by reason ofthelefthand winding of the relay -Ywhich is in opposition to the Yright-hand winding. The spacing signal also causes the brush armlof receiving distributor to rotate once.

e The nopening of theV line by Ytwo stations almost simultaneously could cause Vaninvalid character to appear on rthe line. To prevent suchla character from being read, K11 cannot operate because tube V6Y is not conducting. The'circuit to operate KIS is broken at contacts 9 of K10. The release of K10 at its armature Zand contact 1 again applies ground to thecathode of V6 and the grid of the tube rises exponentially. VWhen its grid reaches ground potential (approximately one-half second after K10 releases) V6 conducts and K11 can operate to provide, at its contacts 3, a probe'pulse to read the received characters.

, Handling keyset traffic-When its invitation character B is received by the station, the probe pulse appears on armature 2 of K9, Fig. V3, because the character reading relays K20, K23 and K24 vwere energized in response to receipt of B by the line relay LRl. If the stationy does not -want to transmit (K9 not'operated) the probe pulse on its armature 2 operates K6 through a circuit compri'sing contact 1 of K9, link y1 andthe winding of K6. Through its contacts 4, K6 locks up to contacts B1 of K7. A probe pulse from ring 65 of the transmitting distributor 22 is transmitted over a circuit including armature 2' and contact T1 of K7, .contacts 6 of K6 and 'through the left hand winding of K8, causing the latter relay to operate.V VAt the end of the probe pulse, that is, justas the distributor brush leaves the segment 65, VK8 locks up through its contacts 5 and the left hand winding of K7, causing K7 to operate. When K8 operated, va path was closed Vthroughlits contacts 5,'to one end of the left hand Winding of K7` but K7 does not operate during the duration ofV the probe pulse since ground is applied to both ends ofl its left hand winding. The operation of K7 at its contacts B1 releases K6 and at its contacts B3, V'K7 opens the short-circuit comprising conductors 77 to 80 across the `distributor to allow the invitation character of thenext station toV be sent.

Switches S1, S2, S3, S4 and S5 are used to setup the character that is to be the invitation character of the ynext, station; those `switches which are closed cause marking pulses to be transmitted and those which are open fresult in spacing pulses transmitted by the distributor 22. 'In'this case it is assumed that the invitation character of the next station is the letter C, which has the second, third and `fourth pulses thereof marking in character, and `switches S2,`S,3 andV S4 are correspondingly closed while switches 'S1 and S51are open and result in thetransmis- I probe pulse from ring 65 -Yin'order to synchronize the ,Y f8. sion of the rst and fth pulses as spacing in character.- When the brushes ofA distributor 22' pass over the start segment S of the segmentedjring 60, the line L is opened;

sending the start pulse of the character.A When the sec-` ond, third and fourth-pulsesof the invitation character are marking,` as in the present example, the line Iis closed through the switches S2, S3, S4, and the segments Y2,3

'and 4, and the ring 61 of the distributor. The probe pulse generated by segment 65 during this rotation'of the, distributor, through contactsV T2 and T3 of YK7 and the right handY winding of KSV causes K8 to release, and

byV means of the right hand winding of K7, which is an aiding coil, holds K7 operated. At the end of the probe pulse from segment 65 of the distributor, K7 releases. This relay is operated and released at the end of each breaking and making of the short circuit across the distributor with the distributor rotation.

The signal` storage and transmitting elements of the keyset are schematically shown inthe transmitting'portion 27a of the keyset, Fig. '2.Y VThe various details of such a keyset do not comprise a part of the instantV invention, and various types of key'sets suitable for generating `and transmitting signalstothe central station'are known in the art, and in Vlwhich thev signals are initiated by pushv buttons, or by a combinationY of push buttons and a coded selector plateV such as disclosed inthe U.S.

Patent to E.V L'. Schmidt, No. 2,564,410, issued August 14, 1951. The signals are temporarily stored onconf tacts `such as. indicated by the groups 86, 87, 88, "89, Y

in Fig. 2, or in any other buier storage from which signal charactersY may successively be transmitted -to an. outgoing circuit.Y When the invitation character for the station, such as the character B, is received, the rotary v switch RS-l is stepped, by the received probe Ypulse from conductor 72, through armature 2 and contact 3 of opcr` ated K9, and the link y2 to the iirst contact of the bankl or level A of the rotaryV switch and through the switch arm of that Ylevel and the winding of the stepping magnet Y. -toradvance theswitch one step. The rotary switch is of the type in which the switch arms are simultaneously stepped to the next contacts in their respective levels A to G upon termination of the stepping pulse. The second contact in the switch bank of level B to which the switch was stepped keepsthe sending distributor 22' shorted at that time.

The sending probe pulse from segment 65 of the transmitting distributor over conductor 82 and the strapped wiring of the switch bank contacts of level A at point 2 steps RS-l to point 3 where the distributor is unshorted on level B. Ground on points 3 of level Cl and level E operatesfKl and K3 thereby connecting the iirst and third segments ofrdistributor ring y to the line. 1 The rotation of the distributor while lRS-lV is on point 3 f sends the character S (irst and thirdpulses marking) which notities the central station that keyset trac Yis 'to be sent. The probe pulse from 165 following the character S steps RS-1 to point 4 to send the iirst information character from the keyset, and .this character is repre-V sented by the upper horizontal row of .contacts 86 to 89 which are permutatively closed depending upon the stored character to be transmitted. If the -rst, second, thirdV i or fourth pulses are to -be marking, as determined by the.V selective closure of contacts 86 to l89 in the first row,V

of the distributor ring 60 to send a marking fifth pulse; Y If the number of marking pulses is odd, the path through K4,K3, K2 and K1 is not provided andthe fth pulse is sentLas spaciug.- 

